DE1123170B - Device for displaying the angular position and the number of complete revolutions of a shaft - Google Patents

Description

Device for displaying the angular position and the number of times that have taken place whole revolutions of a shaft The invention relates to a device for displaying the angular position and the number of complete revolutions of a shaft, with the shaft a first dial for displaying the angular position is firmly connected and shows a number of complete revolutions second dial is rotatably arranged for itself on the shaft, namely as follows, that with each revolution of the first dial, the second dial by one The division is indexed using a pinion which is connected to a part its interlocking with a continuous interlocking and with the second dial connected to the ring gear meshes, with a number of the pinion teeth has a shorter length than the remaining teeth of the pinion, so that on one Front side of the pinion the toothing is interrupted and tooth gaps are formed, which are larger than the tooth gaps on the other face.

Devices of the type mentioned are already known per se. and although they are preferably used in connection with controllable components such. B. resistors, coils, capacitors are used. For example, you can use the The purpose is to indicate the setting of an electrical potentiometer. whose Potentiometer resistor is helically wound, so that the pick-up of the potentiometer has to perform a large number of full revolutions.

In a known embodiment, the one on the first mentioned, dial indicating the angular position of the shaft within one revolution arranged rotatably about an axis that is eccentric to the axis of rotation of the same and meshes, apart from the fact that it is the step-by-step second, the whole Revolutions indicating dial connected to the ring gear meshes, at the same time with a ring gear which is fixedly arranged on the base plate of the device. That When the first dial rotates, the pinion rolls on the one on the base plate arranged ring gear from, so that connected to the second dial The ring gear is also fixed during the rolling movement. The one arranged on the base plate A toothed rim has a tooth gap instead of a tooth at one point and underneath a shoulder three teeth wide. Comes to the Rotation of the first shaft provided to display the angular position the rotated Pinion to the shoulder so it will go over this shoulder with its enlarged tooth gap or his shortened teeth pushed away without rotation, so that in this Movement phase of the gear rim that can be moved together with the second dial, which is kept still during the rolling process of the pinion, is taken along and is advanced by one division. The one fixed to the base plate Ring gear is particular because of its enlarged tooth gap and the underlying one widened shoulder relatively complicated and shortened to manufacture the device.

The invention aims to provide a device free from these deficiencies to display the angular position and the number of complete revolutions to create a wave, in which the application of the specially shaped, to the bottom plate attached ring gear is not required.

Instead of the aforementioned toothed ring with the individual widened gap and the widened shoulder underneath, the device according to the invention uses a much simpler component, namely only a few, e.g. B. two teeth comprehensive tooth segment and a circular running surface underneath, which has a corresponding gap at the point of the tooth gap of the tooth segment.

While in the previously known construction the pinion is constantly in rotation during a rotation of the drive shaft that does not exceed 3601 , this is the case with the device according to the invention only during the switchover beyond the 360 'point. This results in less waste uses of the device according to the invention, especially if the sprockets are chrome-plated injection-molded parts, their service life is limited by the fact that the thin Chrornüberzugsschichten rub off and then protrudes slightly the wear and tear zinc alloy under the same.

The device for displaying the angular position and the number of complete revolutions of a shaft is characterized according to the invention, that the fixed and rotatable pinion with its fully toothed on the building floor Part into the continuous toothing provided on the second dial and engages in a toothed segment arranged on the first dial, which consists of consists of at least two teeth and with an underlying circular running surface is connected, which is a widened tooth gap of the not fully toothed part of the pinion cuts through and partially fills the same and thereby the Prevents pinion from turning as long as the first dial is independent of the second dial rotates, and that with every full revolution of the shaft Tooth of the fully toothed part of the pinion in a gap in the tooth segment and one tooth of the not fully toothed pinion part into one at the point of the gap of the tooth segment lying interruption of the running surface engages.

A preferred embodiment of the invention provides that the tread a ring enclosing the pinion and the toothed segment from two inside extending teeth arranged on the flange surface of the ring.

The invention is illustrated in the drawing using an exemplary embodiment, specifically in connection with a controllable resistor. 1 shows a longitudinal section through a device according to the invention, FIG. 2 shows a side view of the device shown in FIG. 1 , seen from the right, FIG. 3 shows a view similar to FIG. 2, but with the first dial and the button are removed from the device, Fig. 4 is a partial section along the line 4-4 of Fig. 1, Fig. 5 is a partial section along the line 5-5 of Fig. 4 after removal of the pinion, Fig. 6 shows a mounting of the device suitable template.

1 shows a device 10 for displaying the angular position of a shaft in connection with a controllable resistor 11 , which does not form part of the invention. The resistance 11 consists of a cylindrical housing 12, the flat helical Nu 't 13, the turns of a helically wound resistance element 14 receives. Each turn consists of a large number of thinner Windungen14a which are wrapped helically around a core b fourteenth At one end of the housing 12 an externally threaded fitting 15 is attached by welding or the like, which protrudes through a bore 16 in a plate 17; the opposite end of the housing is closed by a cover 18 . In a bore 21 of the fitting piece 15 , a shaft 22 is mounted, in the annular groove of which a split ring 23 or the like rests on the inner end of the fitting piece 15 and prevents axial displacement of the shaft outward.

The shaft 22 carries a displaceable ring 24 which is secured against rotation relative to the shaft 22 by a pin 25 which engages in a longitudinal groove 26 of the shaft. On the ring 24 there is an arm 27 with a profile contact 28 which partially surrounds the resistance element 14. The contact slides along the resistance element when the shaft 22 is rotated, so that the ring 24 is displaced in the longitudinal direction of the shaft. If the shaft 22 is rotated clockwise (according to FIG. 2), the contact 28 follows the turns of the resistance element 14 and moves the ring 24 in the axial direction from right to left (FIG. 1). If, on the other hand, the shaft 22 is rotated counterclockwise, the ring 24 is shifted from left to right. This axial displacement of the ring 24 is limited by stops 29 and 30 which are arranged on the lateral inner surfaces of the housing 12 by way of the arm 27 in such a way that they prevent the movement of the sliding contact 28 beyond the corresponding ends of the resistance element 14.

The resistor 11 can be switched into an electrical circuit, the resistance of which is to be changed via suitable connections (not shown) with the sliding contact 28 and one end of the resistance element 14. The resistor 11 can also be switched as a potentiometer. To measure the set resistance, the position of the sliding contact 28 on the resistance element 14 must be determined. This can be done by determining the number of full turns and the fraction of a turn that the shaft 22 has rotated. This is the task of the display device 10 according to the invention in the form of application described.

An adjusting part 35, which is used to adjust the other parts, lies on the outer surface of the circuit board 17 and is secured by a nut 36 which can be screwed onto the fitting piece 15 and which also serves to fasten the resistor 11 on the circuit board 17 . A plate 37 is located on the outer surface of the setting part 35. A full rotation indicator, which serves as a second dial 38, is rotatably arranged on this. Attached to the outer end of the shaft 22 is a partial rotation indicator, referred to as the first dial 39 , which holds the second dial on the plate 37 and is rotated with a knob 40. An intermittent gear arrangement 41 connects the second dial 38 to it once during each rotation of the first dial 39 so that the second dial is rotated a small distance at the angular velocity of the first dial, i.e. h., the gear assembly 41 rotates the second Zifferrischeibe 38 by one step for each complete revolution of the first Ziffemscheibe 39. The gear assembly 41 is composed of an inwardly directed toothed segment 42 (Fig. 4) on the first digit disc 39 and a ring gear 43 on the second dial 38, which is aligned in the axial direction with the tooth segment 42, and a stepwise working pinion 44 mounted on the plate 37. This constantly meshes with the ring gear 43 of the second dial 38 and is with the tooth segment 42 of the first dial 39 engaged once during each revolution of the first dial 39 and thus rotates the second dial 38 one step further at the end of each full revolution of the first dial. Furthermore, a brake shoe 45 mounted on the plate 37 can be brought into frictional engagement with the first dial 39 by a brake arrangement 46 arranged on the same plate, so that the first dial 39 can be locked in any desired position. In this way, the setting cannot be impaired by vibrations or the like, and the contact 28 is kept in the desired position. An annular cover 47 attached to the plate 37 partially encloses the dials 38 and 39 and holds the parts in their assembled position, particularly before the button 40 is attached to the shaft 22.

The adjusting part 35 is pressed against the outer surface of the board 17 by the nut 36 , the adjusting element and the nut meshing with one another with inclined surfaces 35a and 36a (FIG. 1). A projection 55 on the adjustment member 35 projects inwardly into a recess 56 in the PIatine 17 and a collar 57 projecting outwardly into a recess 58 of the plate 37. Therefore, the setting part 35 sets automatically the Vorrich- tung 10 opposite the resistor 11 in the right location. The end of nut 36 is tapered at 36b and fits into bore 16 when the nut is turned 180 ' for use and adaptation to a thicker board. A conical surface 36c on the nut engages in the surface 35a .

The ringförrnige plate 37 is located on the outer surface of the adjusting member 35 and engages the nut 36, with its concentric segments 36 37 d the plate is engaged and is thereby properly adjusted to the shaft 22nd The plate 37 carries an axially protruding annular guide rail 61 (FIG. 3) which is interrupted by gaps 62 and 63 . The tooth tip surfaces of the ring gear 43 of the second dial 38 form an interrupted cylindrical surface, the diameter of which is slightly larger than the outer diameter of the rail 61 , so that the second dial 38 is mounted on the guide rail 61 in a simple and space-saving manner.

The pinion 44 is rotatably mounted in the gap 62 on a headed pin 66 (FIG. 1) passing through the plate 37 and, due to its arrangement between the toothed segment 42 and the ring gear 43, causes the same direction of rotation of both dials 38, 39, whereby the reading of the disks 38 and 39 is facilitated.

The first dial 39 encloses the button 40. This is connected to the shaft 22 by cap screws 68 and together with the cover 47 holds the second dial 38, the pinion 44 and the brake shoe 45 on the plate 47. The first dial 39 carries the information "0", "10", "20" etc. These digits indicate a partial rotation in decimals and percentages. The annular second dial plate 38 surrounds the first Ziffemscheibe 39 and transmits the numeric data "0", "l", "2" etc. In the arrangement of FIG. 2, only three numbers on the disk 38 at any time by an arc-shaped window 70 in the ring-shaped cover 47 is visible, and this is provided with a marking 71 as a reference point for reading the disks 39 and 38 .

In Fig. 1 , the contact 28 is located when the digits "0" of the discs 39 and 38 coincide with the reference mark 71 (Fig. 2) at the right end of the resistance element 14. If the button 40 is now moved clockwise, the Contact 28 moved to the left (Fig. 1) . Shortly before the end of a full turn of the button 40, which corresponds to one full turn of the sliding contact 28 , the tooth segment 42 of the first dial 39 comes into engagement with the pinion 44 and rotates the second dial 38 by one step, thereby bringing the number »1 « In congruence with the reference mark 71. This indicates that the sliding contact 28 has experienced a full forward rotation over one turn of the resistance element 14. A short, arched mark 72, preferably in red, is attached to the number disk 39 near the number “0” and between the numbers “0” and “90”. If the mark 72 is in the vicinity of the mark 71 , this indicates that, when reading the moving dial 38 , it must be taken into account that the tooth segment 42 is in engagement with the pinion 44 and is about to move the disk 38 by one step to turn.

The second dial 38 thus shows the number of complete revolutions or turns of the helical resistance element 14 by which the sliding contact 28 has advanced from its zero or initial position, and the first dial 39 shows in decimals the fraction of such a complete revolution or Turn on. If z. B. cover the number "5" of the first disk 38 and the number "40" of the second disk 39 with the reference mark 71 , the reader learns that the sliding contact 28 has advanced by 5.40 turns of the resistance element 14 from its zero position. If z. For example, if the resistance element 14 has ten turns, this reading indicates that the contact 28 has traversed 54.0% of the length of the element 14. The dials 39 and 38 are calibrated in full or tenths of a turn; however, they can also be calibrated in other units, for example in resistance values.

Since the button 40 is rigidly connected to the shaft 22, there is a direct connection between the decimal number disk 39 and the sliding contact 28, so that its angular position is always displayed exactly without dead gear. Dead gear in the intermittent gear wheel arrangement 41 does not affect the accuracy of the display of the device 10 due to the stepwise rotation of the second dial 38 , so that even small reading errors of the angular separation of the disk 38 with respect to the mark 71 are insignificant.

In order to prevent the operator from accidentally rotating the second dial 38 out of its respective position, a locking device is provided. This consists of stops 76 ' formed on the pinion 44 in the form of axially elongated teeth with widened tooth gaps and an annular running surface 77 connected to the first dial 39 and interrupted at the tooth segment 42. When the toothed segment 42 is out of engagement with the pinion 44, align two stop teeth 76 ' with the running surface 77 and thus prevent the rotation of the pinion, while the shorter teeth of the pinion engage the teeth of the ring gear 43 and allow the first dial 39 to rotate. Since the tooth segment 42 on the disk 39 interrupts the annular running surface 77 , the stops 76 'of the pinion 44 do not rest on the running surface 77 when the tooth segment is in engagement with the pinion, which only allows the second dial 38 to rotate. This is locked against rotation until the toothed segment 42 is in engagement with the pinion 44 in order to rotate the second dial 38 by one step.

To lock the sliding contact 28 in a desired position, the brake shoe 45 is arranged between the guide rail 61 and a hub 81 on the first dial 39 in frictional engagement with the hub which engages the segments 36d of the nut 36 to align these parts. One end 82 of the shoe 45 protrudes into the gap 63 of the guide rail 61 and is connected therein to the plate 37 by means of a coupling pin 83 extending through the plate.

The brake assembly 46, which presses the brake shoe 45 into frictional engagement with the hub 81 , consists of a flat ring 84 which is rotatable in an annular recess 85 in the rear surface of the plate 37 and sits on the pins 66 and 83. These therefore not only serve as pivot pins for the slot] 44 and the brake shoe 45, but also hold the ring 84 firmly in the recess 85. A thumb 86 of the ring 84 protrudes forward through an arcuate slot 87 in the plate 37 into the space between the brake shoe 45 and the ring rail 61. The diameter of the brake shoe 45 increases progressively from the rotatable end 82 , so that when the ring 84 is rotated Clockwise (FIG. 3) the thumb 86 presses the brake shoe inward into frictional engagement with the hub 81 of the first dial 39 and locks it in the desired position by friction. The ring 84 is rotated by means of a radially outwardly directed lever 88 , the outer end of which is provided with a handle 89. The rear surface of the plate 37 and the periphery of the cover 47 have not shown recesses in which the lever 88 can move when it is rotated between the position shown in Fig. 3 in which it releases the brake shoe 45 and a position in which the thumb 86 pulls the brake shoe in frictional engagement with the hub 81.

The jacket 93 of the annular cover 47 (Fig. 1) is pressed against the periphery of the plate 37 which is grooved or fluted to hold the jacket 93 in place by friction. Furthermore, the cover 47 carries an inwardly inclined flange 94 in which the arcuate window 70 is located. The flange extends inwardly over the circumference of the first dial 39 and holds it on the plate 37 so that the second disk 38, the pinion 44 and the brake shoe 45 are secured in their position. The flange 94 exerts this effect prior to the attachment of the device 10 to the circuit board 17 and prior to the fastening of the button 40 of the first dial 39 on the shaft 22. After the button 40 is attached, it also holds the parts between it and the plate 37 in their assembled position. It should be noted that the split ring 23, as already mentioned, prevents the axial movement of the shaft 22 to the right (FIG. 1). Since the button 40 is mounted on the shaft 22, the device 10 prevents axial movement of the shaft 22 to the left (Fig. 1).

A template 96 is used to establish the holes 16 and 56 in the board 17 and to register the plate 37 and the other parts. The template 96 is provided with a pressure sensitive adhesive so that it will easily adhere to the board and the holes 16 and 56 are scribed thereon so that they can be easily drilled in the correct locations. An arcuate part line 97 is also marked on the template in such a way that the plate 37 and the cover 47 can be covered with its recesses.

Claims (3)

PATENT CLAIMS-1. Device for displaying the angular position and the number of complete revolutions of a shaft, in which a first dial for displaying the angular position is firmly connected to the shaft and a second dial for displaying the number of complete revolutions is arranged on the shaft so that it can rotate , in such a way that with each revolution of the first dial, the second dial is indexed by one division using a pinion which meshes with a part of its toothing with a toothed wheel that has a continuous toothing and is connected to the second dial, with a number of Pinion teeth have a shorter length than the other teeth of the pinion, so that the toothing is interrupted on one end face of the pinion and tooth gaps are formed which are larger than the tooth gaps on the other end face, characterized in that the housing bottom (37) is stationary and rotatably mounted Rit zel (44) engages with its fully toothed part in the continuous toothing (43 ) provided on the second dial (38) and in a toothed segment (42) arranged on the first dial (39) , which consists of at least two teeth and with one underlying circular running surface (77) is connected, which cuts through a widened tooth gap of the not fully toothed part of the pinion (44) and partially fills the same and thereby prevents the pinion from rotating as long as the first dial (39) is independent of the second dial (38) rotates, and that with each full revolution of the shaft (22) a tooth (76) of the fully toothed part of the pinion (44) in a gap in the toothed segment (42) and a tooth (76 ') of the not fully toothed pinion part engages in an interruption of the running surface (77) located at the point of the gap in the toothed segment (42). 2. Apparatus according to claim 1, characterized in that the running surface (77) is a ring surrounding the pinion (44) and the toothed segment (42) consists of two inwardly extending teeth arranged on the flange surface of the ring (77). 3. Apparatus according to claim 1 or 2, characterized in that an interrupted guide ring (61) is provided on the base plate (37) , in the gap of which the pinion (44) is arranged and around which the ring formed as a toothed ring and gradually further switched second dial (38) connected continuous toothing (43) is arranged. Contemplated publications: USA. Patents No. 2323608, 2356914, 2443064, 2539575..